Abstract
This work had the purpose of evaluating the efficiency of the pretreatment with alkaline hydrogen peroxide of pineapple bagasse in order to obtain fermentable sugars by applying acid and enzymatic hydrolysis to said residue. Four experimental designs were applied to study the best conditions for the pre-treatment. Total reducing sugars (TRS) concentration was the response and hydrogen peroxide concentration, time and temperature were the independent variables. The studies were conducted using pineapple bagasse with particle sizes of 20 mesh and 48 mesh. Acid saccharification, with 2.9% sulfuric acid (v/v), following the pre-treatment, yielded TRS concentrations that reached 0.094 g of TRS/g of raw bagasse for 20 mesh and 0.101 g of TRS/g of raw bagasse for 48 mesh. The enzymatic saccharification, with 9 FPU/g cellulase and 2% (m/v) of bagasse, reached 0.063 g of TRS/g of raw bagasse for both particle sizes. The peroxide concentration showed a significant influence, the use of high concentrations reduced the TRS output in both hydrolysis. With the results found in this work, it is possible to infer the feasibility of applying pineapple bagasse as a lignocellulosic raw material.
Highlights
There is a correlation between energy and prosperity, making energy indispensable for modern societies (Nakanishi et al, 2018)
Renewable energy sources are an upcoming trend, and lignocellulosic biomass is recognized as a prominent raw material for the production of biofuels and other value-added products, it can be of value to the global energy supply (Chaturved & Verma, 2013)
At the end of each saccharification, the total reducing sugars (TRS) were determined according to methodology described by Miller (1959) and the results were presented in g of TRS/g of raw bagasse
Summary
There is a correlation between energy and prosperity, making energy indispensable for modern societies (Nakanishi et al, 2018). According to Oliveira (2012), the main effect of exposing the lignocellulosic matrix to pretreatment agents for extended periods is cellulose loss, resulting in low output in the process This step is necessary to reduce cellulose’s degree of crystallinity; dissociate the lignin-cellulose complex; increase biomass surface area; preserve pentoses maximizing the sugars output; and minimizing the generation of process inhibitors, in both saccharification and fermentation steps (Shen et al, 2011, Santos et al, 2018). This step is a major bottleneck in second-generation ethanol production. The response analyzed was the total reducing sugars (TRS) output, to evaluate the application in producing second-generation (2G) ethanol
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